|Publication number||US7209494 B1|
|Application number||US 09/694,870|
|Publication date||Apr 24, 2007|
|Filing date||Oct 24, 2000|
|Priority date||Oct 24, 2000|
|Publication number||09694870, 694870, US 7209494 B1, US 7209494B1, US-B1-7209494, US7209494 B1, US7209494B1|
|Inventors||Dan M Griffin, Samuel C. Kingston, Delon K. Jones, Randal R. Sylvester|
|Original Assignee||L-3 Communications Corporation|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (12), Referenced by (3), Classifications (12), Legal Events (3)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This invention relates generally to Time Division Duplex (TDD) communication systems and, more particularly, relates to TDD communication systems wherein bidirectional digital data links are established between an Access Point (AP) or Hub and a plurality of customer premise equipment (CPE).
In a TDD system two entities share a common carrier frequency channel for conducting bidirectional communications. In order to avoid interference and collisions, a first entity transmits during a first time period while a second entity receives the transmission from the first entity, and then the second entity transmits during a second time period while the first entity receives the transmission from the second entity. The first and second time periods are then repeated. In this manner it can be guaranteed that the two entities will not interfere with each others transmissions. Some amount of guard time can be inserted between the first and second periods, and between periods, to ensure that one entity does not begin transmitting before the other finishes.
At the start of a transmission the receiving entity must acquire the received signal, resolve any frequency uncertainty and lock to the carrier frequency and carrier phase, and then begin demodulating the modulated carrier. This can require some significant amount of time. Furthermore, the entire transmission might be missed if the receiver is unable to successfully acquire and lock to the received carrier during the transmission period.
As can be appreciated, it is desirable to provide an ability to make the received signal acquisition and carrier frequency lock processes occur as rapidly as possible. One approach provides a synchronous timing scheme wherein the basic frequency references of both entities are, ideally, identical. For example, the frequency reference of the AP or Hub is declared to be a master frequency reference, and the local frequency references of the CPEs are slaved to the AP frequency reference. Unfortunately, no frequency reference is ideal, and some drift can occur between the various frequency references of the CPEs and the AP. This frequency drift causes a phase and frequency shift between the AP and a receiving CPE, which can lead to received signal demodulation errors.
It is a first object and advantage of this invention to provide a method and apparatus for providing an improved received signal acquisition and carrier frequency lock process.
It is another object and advantage of this invention to provide a method and apparatus for use in a communication system that provides an improved received signal acquisition and carrier frequency lock process.
It is a further object and advantage of this invention to provide a method and apparatus for use in a TDD system that pre-corrects a frequency of a transmission from a transmitting entity so as to compensate for a detected amount of frequency error between the transmitting entity and the receiving entity, thereby improving the ability of receiving entity to acquire, lock to, and demodulate the received transmission.
The foregoing and other problems are overcome and the objects of the invention are realized by methods and apparatus in accordance with embodiments of this invention.
A Time Division Duplex (TDD), Code Division Multiple Access (CDMA) communication system includes a plurality of Customer Premises Equipment (CPE) and an Access Point (AP) that communicate through RF links. A CPE contains a receiver baseband subsystem and a transmitter baseband subsystem, and further contains receiver circuitry operable during a receive period for receiving an RF carrier from the AP and for deriving a receiver tracking signal that is indicative of a frequency and phase shift between the received RF carrier and a reference signal. The receiver circuitry further includes a digital phase shifter and a frequency to phase accumulator that together rotate the receiver baseband signal by some amount of frequency and phase and in a direction indicated by the receiver tracking signal. The CPE further contains, in accordance with an aspect of this invention, multiplexing circuitry for sharing the digital phase shifter and frequency to phase accumulator circuits between the receiver baseband subsystem and the transmitter baseband subsystem. The frequency to phase accumulator is loaded during a next transmission period for operating the digital phase shifter to correct a frequency of a transmitter baseband signal by an amount indicated by the receiver tracking signal, and in a direction opposite to the direction indicated by the receiver tracking signal. The effect is to pre-compensate an RF carrier that is transmitted to the AP from the CPE so as to reduce carrier acquisition time at a receiver of the AP.
The CPE may further contain sample and hold circuitry that is responsive to an end of the receive period for storing the receiver tracking frequency error. This stored frequency error is inverted and loaded into the frequency to phase accumulator which drives the digital phase shifter at the compensated frequency during the next transmission period.
The above set forth and other features of the invention are made more apparent in the ensuing Detailed Description of the Invention when read in conjunction with the attached Drawings, wherein:
Each CPE 10 is preferably comprised of a CDMA system 10A, assumed to generally include spreaders and despreaders, as well as data phase modulators (transmit), data phase demodulators (receive), frequency reference(s) such as local oscillators (LOs), carrier loop tracking circuits, possibly signal interleavers and deinterleavers, and other circuitry known to those skilled in this art. The CDMA system 10A is, however, modified in accordance with the teachings of this invention in a manner described below. The CDMA system 10A is coupled between a transceiver 10B and a suitable data processor 10C. The transceiver 10B is preferably an RF transceiver providing wireless RF link 11 communication capabilities, preferably but not limited to line of sight (LOS) communication, with a similar RF transceiver 12B of the AP 12. However, in other embodiments the transceivers 10B, 12B may be implemented as optical transceivers.
The data processor 10C could have the functionality of a conventional single user personal computer or workstation, and/or it may serve as a front-end for a local area network (LAN) 18 having a plurality of data processors (DPs) 20 coupled thereto. The exact nature and use of the CPE 10 is not germane to an understanding of the teachings of this invention. It is noted that some or all of the CPEs may also have voice capability (e.g., a microphone and a speaker), and that voice connections can also be made over the wireless links 11.
The Hub or Access Point (AP) 12 is similarly constructed to include a CDMA section 12A, preferably a multi-channel CDMA system for accommodating the plurality of CPEs 10, at least one but preferably a plurality of the transceivers 12B for establishing the wireless links 11 with the CPEs 10, and an Access Point processor 12C for controlling the overall operation of the AP 12. The AP processor 12C is preferably bidirectionally coupled to at least one data communication network 14 which, in turn, can provide access to the Internet and World Wide Web (WWW). In this manner, and by example, one of the DPs 20 can be used to access the WWW via the LAN 18, CPE 10, wireless link 11, AP 12 and the data communication network 14.
During operation, a local oscillator of the AP 12 is preferably frequency and phase synchronous with a local oscillator of the CPE 10. However, some amount of frequency and phase shift between the two LOs will typically be present. A phase shift may also be introduced due to RF channel impairments between the AP 12 and the CPE 10. As such, at least the CPE 10 is provided with carrier loop tracking circuitry (not shown) for frequency and phase locking the local oscillator of the CPE 10 to the incoming received carrier signal from the AP 12.
Referring first to the upper part of
The FPA 44 basically functions as an accumulator that adds the value output by a sample and hold (S/H) 42 each clock period, thereby changing the phase that the DPS 28 receives each clock to produce a frequency correction. The combination thus corrects for a small frequency error. The frequency generated is given by:
fo=((clock frequency)×S/H value)/Length of accumulator,
e.g., 232 if a 32-bit accumulator is used.
In accordance with this invention an input multiplexer (MUX) 32 is provided at the frontend of the DPS 28. The MUX 32 is controlled with a transmit/receive (XMIT/RCV) signal so as to couple, during the TDD receive period and in a conventional fashion, the received baseband I and Q signals to the input of the DPS 28. From the output of the DPS 28 the rotated signals are applied to the despreader 30.
A frequency/phase loop filter that forms a part of the carrier loop tracking circuit contains a measure of the receive frequency error and also the phase error of the received signal. At the end of a receive burst the receive frequency error is held by the sample and hold (S/H) 42, inverted and applied to the frequency to phase accumulator 44. This signal then drives the digital phase shifter 28 to generate a frequency opposite to that of the receive frequency error, thus pre-correcting a transmitted frequency error. As such, when the AP 12 receives the CPE 10 transmission the CDMA system 12A can more rapidly and reliably carrier lock to the received CPE signal, and then despread and demodulate the received signal.
The output of the DPS 28 is provided to I and Q filters 40A, 40B, respectively, and then to transmit path I and Q digital to analog converters (D/As) 40C, 40D, respectively. These signals are subsequently upconverted to the desired transmission carrier frequency.
Referring now as well to
In accordance with the teachings of this invention the disclosed circuitry of the MUX 32 cooperates with the DPS 28, the frequency to phase accumulator 44, and the output signal (receiver tracking signal) of the carrier loop tracking circuit to correct the frequency of the transmitter baseband I and Q channels.
To facilitate this operation the sample and hold (S/H) circuit 42 can be provided if the output signal of the carrier loop tracking circuit is an analog signal. If the output signal of the carrier loop tracking circuit is instead a digital signal, then the sample and hold function can be implemented with a simple register or with a memory location for storing the last value of the receiver tracking signal during the next transmission period.
In operation, the output signal of the carrier loop tracking circuit is sampled during the receive period and passed through to the frequency to phase accumulator 44. The last frequency-only component of the loop filter is then inverted and held at the end of the receive period or burst. While being held the inverted signal is applied to the frequency to phase accumulator 44, which drives the DPS 28 to create a correction frequency, for the duration of the transmit period. In this manner the amount of frequency correction applied by the DPS 28 to the transmitter baseband I and Q channels, during a single transmission period, is a function of the amount of frequency error detected by the carrier loop tracking circuit at the end of the previous receive period. The use of a single value for the frequency correction during the transmission period is possible since the transmit and receive periods are typically much shorter than the time over which the signal propagation of the RF channel changes, and are also typically shorter than the time over which the CPE 10 LO drifts by a significant amount with respect to the AP 12 LO. In the preferred embodiment of this invention the transmit and receive periods each have a typical duration in the range of about 0.5 milliseconds to about 4 milliseconds, a period of time that is typically much smaller than signal propagation time constants experienced in the RF channel, such as slow fades, which can be seconds and tens of seconds, and is also smaller than the typical (short term) LO drift rate.
The use of this invention enables the AP 12 to more quickly acquire the carrier phase from the CPE 10, as the frequency error has been substantially removed. This enables the transmitted signal to arrive at the AP 12 with little or no frequency ambiguity due to RF channel impairments and frequency-influencing conditions that may exist between the CPE 10 and the AP 12, such as frequency shifts between the CPE 10 and AP 12 LOs. As such, non-coherent clocks may be employed between the CPE 10 and the AP 12, thus simplifying the overall system design and operation.
While the invention has been particularly shown and described with respect to preferred embodiments thereof, it will be understood by those skilled in the art that changes in form and details may be made therein without departing from the scope and spirit of the invention. For example, while
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|U.S. Classification||370/516, 375/E01.016, 370/507, 370/503|
|Cooperative Classification||H04L2027/003, H04L27/0014, H04B1/7085, H04L2027/0077, H04L2027/0022|
|European Classification||H04B1/7085, H04L27/00R|
|Oct 24, 2000||AS||Assignment|
Owner name: L-3 COMMUNICATIONS CORPORATION, NEW YORK
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:GRIFFIN, DAN M.;KINGSTON, SAMUEL C.;JONES, DELON K.;AND OTHERS;REEL/FRAME:011280/0414;SIGNING DATES FROM 20001004 TO 20001016
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